"use strict";

var _interopRequireDefault = require("@babel/runtime/helpers/interopRequireDefault");
Object.defineProperty(exports, "__esModule", {
  value: true
});
exports.createParse = void 0;
var _extends2 = _interopRequireDefault(require("@babel/runtime/helpers/extends"));
var _factory = require("../utils/factory.js");
var _is = require("../utils/is.js");
var _collection = require("../utils/collection.js");
var _number = require("../utils/number.js");
var _object = require("../utils/object.js");
const name = 'parse';
const dependencies = ['typed', 'numeric', 'config', 'AccessorNode', 'ArrayNode', 'AssignmentNode', 'BlockNode', 'ConditionalNode', 'ConstantNode', 'FunctionAssignmentNode', 'FunctionNode', 'IndexNode', 'ObjectNode', 'OperatorNode', 'ParenthesisNode', 'RangeNode', 'RelationalNode', 'SymbolNode'];
const createParse = exports.createParse = /* #__PURE__ */(0, _factory.factory)(name, dependencies, _ref => {
  let {
    typed,
    numeric,
    config,
    AccessorNode,
    ArrayNode,
    AssignmentNode,
    BlockNode,
    ConditionalNode,
    ConstantNode,
    FunctionAssignmentNode,
    FunctionNode,
    IndexNode,
    ObjectNode,
    OperatorNode,
    ParenthesisNode,
    RangeNode,
    RelationalNode,
    SymbolNode
  } = _ref;
  /**
   * Parse an expression. Returns a node tree, which can be evaluated by
   * invoking node.evaluate().
   *
   * Note the evaluating arbitrary expressions may involve security risks,
   * see [https://mathjs.org/docs/expressions/security.html](https://mathjs.org/docs/expressions/security.html) for more information.
   *
   * Syntax:
   *
   *     math.parse(expr)
   *     math.parse(expr, options)
   *     math.parse([expr1, expr2, expr3, ...])
   *     math.parse([expr1, expr2, expr3, ...], options)
   *
   * Example:
   *
   *     const node1 = math.parse('sqrt(3^2 + 4^2)')
   *     node1.compile().evaluate() // 5
   *
   *     let scope = {a:3, b:4}
   *     const node2 = math.parse('a * b') // 12
   *     const code2 = node2.compile()
   *     code2.evaluate(scope) // 12
   *     scope.a = 5
   *     code2.evaluate(scope) // 20
   *
   *     const nodes = math.parse(['a = 3', 'b = 4', 'a * b'])
   *     nodes[2].compile().evaluate() // 12
   *
   * See also:
   *
   *     evaluate, compile
   *
   * @param {string | string[] | Matrix} expr          Expression to be parsed
   * @param {{nodes: Object<string, Node>}} [options]  Available options:
   *                                                   - `nodes` a set of custom nodes
   * @return {Node | Node[]} node
   * @throws {Error}
   */
  const parse = typed(name, {
    string: function (expression) {
      return parseStart(expression, {});
    },
    'Array | Matrix': function (expressions) {
      return parseMultiple(expressions, {});
    },
    'string, Object': function (expression, options) {
      const extraNodes = options.nodes !== undefined ? options.nodes : {};
      return parseStart(expression, extraNodes);
    },
    'Array | Matrix, Object': parseMultiple
  });
  function parseMultiple(expressions) {
    let options = arguments.length > 1 && arguments[1] !== undefined ? arguments[1] : {};
    const extraNodes = options.nodes !== undefined ? options.nodes : {};

    // parse an array or matrix with expressions
    return (0, _collection.deepMap)(expressions, function (elem) {
      if (typeof elem !== 'string') throw new TypeError('String expected');
      return parseStart(elem, extraNodes);
    });
  }

  // token types enumeration
  const TOKENTYPE = {
    NULL: 0,
    DELIMITER: 1,
    NUMBER: 2,
    SYMBOL: 3,
    UNKNOWN: 4
  };

  // map with all delimiters
  const DELIMITERS = {
    ',': true,
    '(': true,
    ')': true,
    '[': true,
    ']': true,
    '{': true,
    '}': true,
    '"': true,
    '\'': true,
    ';': true,
    '+': true,
    '-': true,
    '*': true,
    '.*': true,
    '/': true,
    './': true,
    '%': true,
    '^': true,
    '.^': true,
    '~': true,
    '!': true,
    '&': true,
    '|': true,
    '^|': true,
    '=': true,
    ':': true,
    '?': true,
    '==': true,
    '!=': true,
    '<': true,
    '>': true,
    '<=': true,
    '>=': true,
    '<<': true,
    '>>': true,
    '>>>': true
  };

  // map with all named delimiters
  const NAMED_DELIMITERS = {
    mod: true,
    to: true,
    in: true,
    and: true,
    xor: true,
    or: true,
    not: true
  };
  const CONSTANTS = {
    true: true,
    false: false,
    null: null,
    undefined
  };
  const NUMERIC_CONSTANTS = ['NaN', 'Infinity'];
  const ESCAPE_CHARACTERS = {
    '"': '"',
    "'": "'",
    '\\': '\\',
    '/': '/',
    b: '\b',
    f: '\f',
    n: '\n',
    r: '\r',
    t: '\t'
    // note that \u is handled separately in parseStringToken()
  };
  function initialState() {
    return {
      extraNodes: {},
      // current extra nodes, must be careful not to mutate
      expression: '',
      // current expression
      comment: '',
      // last parsed comment
      index: 0,
      // current index in expr
      token: '',
      // current token
      tokenType: TOKENTYPE.NULL,
      // type of the token
      nestingLevel: 0,
      // level of nesting inside parameters, used to ignore newline characters
      conditionalLevel: null // when a conditional is being parsed, the level of the conditional is stored here
    };
  }

  /**
   * View upto `length` characters of the expression starting at the current character.
   *
   * @param {Object} state
   * @param {number} [length=1] Number of characters to view
   * @returns {string}
   * @private
   */
  function currentString(state, length) {
    return state.expression.substr(state.index, length);
  }

  /**
   * View the current character. Returns '' if end of expression is reached.
   *
   * @param {Object} state
   * @returns {string}
   * @private
   */
  function currentCharacter(state) {
    return currentString(state, 1);
  }

  /**
   * Get the next character from the expression.
   * The character is stored into the char c. If the end of the expression is
   * reached, the function puts an empty string in c.
   * @private
   */
  function next(state) {
    state.index++;
  }

  /**
   * Preview the previous character from the expression.
   * @return {string} cNext
   * @private
   */
  function prevCharacter(state) {
    return state.expression.charAt(state.index - 1);
  }

  /**
   * Preview the next character from the expression.
   * @return {string} cNext
   * @private
   */
  function nextCharacter(state) {
    return state.expression.charAt(state.index + 1);
  }

  /**
   * Get next token in the current string expr.
   * The token and token type are available as token and tokenType
   * @private
   */
  function getToken(state) {
    state.tokenType = TOKENTYPE.NULL;
    state.token = '';
    state.comment = '';

    // skip over ignored characters:
    while (true) {
      // comments:
      if (currentCharacter(state) === '#') {
        while (currentCharacter(state) !== '\n' && currentCharacter(state) !== '') {
          state.comment += currentCharacter(state);
          next(state);
        }
      }
      // whitespace: space, tab, and newline when inside parameters
      if (parse.isWhitespace(currentCharacter(state), state.nestingLevel)) {
        next(state);
      } else {
        break;
      }
    }

    // check for end of expression
    if (currentCharacter(state) === '') {
      // token is still empty
      state.tokenType = TOKENTYPE.DELIMITER;
      return;
    }

    // check for new line character
    if (currentCharacter(state) === '\n' && !state.nestingLevel) {
      state.tokenType = TOKENTYPE.DELIMITER;
      state.token = currentCharacter(state);
      next(state);
      return;
    }
    const c1 = currentCharacter(state);
    const c2 = currentString(state, 2);
    const c3 = currentString(state, 3);
    if (c3.length === 3 && DELIMITERS[c3]) {
      state.tokenType = TOKENTYPE.DELIMITER;
      state.token = c3;
      next(state);
      next(state);
      next(state);
      return;
    }

    // check for delimiters consisting of 2 characters
    if (c2.length === 2 && DELIMITERS[c2]) {
      state.tokenType = TOKENTYPE.DELIMITER;
      state.token = c2;
      next(state);
      next(state);
      return;
    }

    // check for delimiters consisting of 1 character
    if (DELIMITERS[c1]) {
      state.tokenType = TOKENTYPE.DELIMITER;
      state.token = c1;
      next(state);
      return;
    }

    // check for a number
    if (parse.isDigitDot(c1)) {
      state.tokenType = TOKENTYPE.NUMBER;

      // check for binary, octal, or hex
      const c2 = currentString(state, 2);
      if (c2 === '0b' || c2 === '0o' || c2 === '0x') {
        state.token += currentCharacter(state);
        next(state);
        state.token += currentCharacter(state);
        next(state);
        while (parse.isHexDigit(currentCharacter(state))) {
          state.token += currentCharacter(state);
          next(state);
        }
        if (currentCharacter(state) === '.') {
          // this number has a radix point
          state.token += '.';
          next(state);
          // get the digits after the radix
          while (parse.isHexDigit(currentCharacter(state))) {
            state.token += currentCharacter(state);
            next(state);
          }
        } else if (currentCharacter(state) === 'i') {
          // this number has a word size suffix
          state.token += 'i';
          next(state);
          // get the word size
          while (parse.isDigit(currentCharacter(state))) {
            state.token += currentCharacter(state);
            next(state);
          }
        }
        return;
      }

      // get number, can have a single dot
      if (currentCharacter(state) === '.') {
        state.token += currentCharacter(state);
        next(state);
        if (!parse.isDigit(currentCharacter(state))) {
          // this is no number, it is just a dot (can be dot notation)
          state.tokenType = TOKENTYPE.DELIMITER;
          return;
        }
      } else {
        while (parse.isDigit(currentCharacter(state))) {
          state.token += currentCharacter(state);
          next(state);
        }
        if (parse.isDecimalMark(currentCharacter(state), nextCharacter(state))) {
          state.token += currentCharacter(state);
          next(state);
        }
      }
      while (parse.isDigit(currentCharacter(state))) {
        state.token += currentCharacter(state);
        next(state);
      }
      // check for exponential notation like "2.3e-4", "1.23e50" or "2e+4"
      if (currentCharacter(state) === 'E' || currentCharacter(state) === 'e') {
        if (parse.isDigit(nextCharacter(state)) || nextCharacter(state) === '-' || nextCharacter(state) === '+') {
          state.token += currentCharacter(state);
          next(state);
          if (currentCharacter(state) === '+' || currentCharacter(state) === '-') {
            state.token += currentCharacter(state);
            next(state);
          }
          // Scientific notation MUST be followed by an exponent
          if (!parse.isDigit(currentCharacter(state))) {
            throw createSyntaxError(state, 'Digit expected, got "' + currentCharacter(state) + '"');
          }
          while (parse.isDigit(currentCharacter(state))) {
            state.token += currentCharacter(state);
            next(state);
          }
          if (parse.isDecimalMark(currentCharacter(state), nextCharacter(state))) {
            throw createSyntaxError(state, 'Digit expected, got "' + currentCharacter(state) + '"');
          }
        } else if (nextCharacter(state) === '.') {
          next(state);
          throw createSyntaxError(state, 'Digit expected, got "' + currentCharacter(state) + '"');
        }
      }
      return;
    }

    // check for variables, functions, named operators
    if (parse.isAlpha(currentCharacter(state), prevCharacter(state), nextCharacter(state))) {
      while (parse.isAlpha(currentCharacter(state), prevCharacter(state), nextCharacter(state)) || parse.isDigit(currentCharacter(state))) {
        state.token += currentCharacter(state);
        next(state);
      }
      if ((0, _object.hasOwnProperty)(NAMED_DELIMITERS, state.token)) {
        state.tokenType = TOKENTYPE.DELIMITER;
      } else {
        state.tokenType = TOKENTYPE.SYMBOL;
      }
      return;
    }

    // something unknown is found, wrong characters -> a syntax error
    state.tokenType = TOKENTYPE.UNKNOWN;
    while (currentCharacter(state) !== '') {
      state.token += currentCharacter(state);
      next(state);
    }
    throw createSyntaxError(state, 'Syntax error in part "' + state.token + '"');
  }

  /**
   * Get next token and skip newline tokens
   */
  function getTokenSkipNewline(state) {
    do {
      getToken(state);
    } while (state.token === '\n'); // eslint-disable-line no-unmodified-loop-condition
  }

  /**
   * Open parameters.
   * New line characters will be ignored until closeParams(state) is called
   */
  function openParams(state) {
    state.nestingLevel++;
  }

  /**
   * Close parameters.
   * New line characters will no longer be ignored
   */
  function closeParams(state) {
    state.nestingLevel--;
  }

  /**
   * Checks whether the current character `c` is a valid alpha character:
   *
   * - A latin letter (upper or lower case) Ascii: a-z, A-Z
   * - An underscore                        Ascii: _
   * - A dollar sign                        Ascii: $
   * - A latin letter with accents          Unicode: \u00C0 - \u02AF
   * - A greek letter                       Unicode: \u0370 - \u03FF
   * - A mathematical alphanumeric symbol   Unicode: \u{1D400} - \u{1D7FF} excluding invalid code points
   *
   * The previous and next characters are needed to determine whether
   * this character is part of a unicode surrogate pair.
   *
   * @param {string} c      Current character in the expression
   * @param {string} cPrev  Previous character
   * @param {string} cNext  Next character
   * @return {boolean}
   */
  parse.isAlpha = function isAlpha(c, cPrev, cNext) {
    return parse.isValidLatinOrGreek(c) || parse.isValidMathSymbol(c, cNext) || parse.isValidMathSymbol(cPrev, c);
  };

  /**
   * Test whether a character is a valid latin, greek, or letter-like character
   * @param {string} c
   * @return {boolean}
   */
  parse.isValidLatinOrGreek = function isValidLatinOrGreek(c) {
    return /^[a-zA-Z_$\u00C0-\u02AF\u0370-\u03FF\u2100-\u214F]$/.test(c);
  };

  /**
   * Test whether two given 16 bit characters form a surrogate pair of a
   * unicode math symbol.
   *
   * https://unicode-table.com/en/
   * https://www.wikiwand.com/en/Mathematical_operators_and_symbols_in_Unicode
   *
   * Note: In ES6 will be unicode aware:
   * https://stackoverflow.com/questions/280712/javascript-unicode-regexes
   * https://mathiasbynens.be/notes/es6-unicode-regex
   *
   * @param {string} high
   * @param {string} low
   * @return {boolean}
   */
  parse.isValidMathSymbol = function isValidMathSymbol(high, low) {
    return /^[\uD835]$/.test(high) && /^[\uDC00-\uDFFF]$/.test(low) && /^[^\uDC55\uDC9D\uDCA0\uDCA1\uDCA3\uDCA4\uDCA7\uDCA8\uDCAD\uDCBA\uDCBC\uDCC4\uDD06\uDD0B\uDD0C\uDD15\uDD1D\uDD3A\uDD3F\uDD45\uDD47-\uDD49\uDD51\uDEA6\uDEA7\uDFCC\uDFCD]$/.test(low);
  };

  /**
   * Check whether given character c is a white space character: space, tab, or enter
   * @param {string} c
   * @param {number} nestingLevel
   * @return {boolean}
   */
  parse.isWhitespace = function isWhitespace(c, nestingLevel) {
    // TODO: also take '\r' carriage return as newline? Or does that give problems on mac?
    return c === ' ' || c === '\t' || c === '\n' && nestingLevel > 0;
  };

  /**
   * Test whether the character c is a decimal mark (dot).
   * This is the case when it's not the start of a delimiter '.*', './', or '.^'
   * @param {string} c
   * @param {string} cNext
   * @return {boolean}
   */
  parse.isDecimalMark = function isDecimalMark(c, cNext) {
    return c === '.' && cNext !== '/' && cNext !== '*' && cNext !== '^';
  };

  /**
   * checks if the given char c is a digit or dot
   * @param {string} c   a string with one character
   * @return {boolean}
   */
  parse.isDigitDot = function isDigitDot(c) {
    return c >= '0' && c <= '9' || c === '.';
  };

  /**
   * checks if the given char c is a digit
   * @param {string} c   a string with one character
   * @return {boolean}
   */
  parse.isDigit = function isDigit(c) {
    return c >= '0' && c <= '9';
  };

  /**
   * checks if the given char c is a hex digit
   * @param {string} c   a string with one character
   * @return {boolean}
   */
  parse.isHexDigit = function isHexDigit(c) {
    return c >= '0' && c <= '9' || c >= 'a' && c <= 'f' || c >= 'A' && c <= 'F';
  };

  /**
   * Start of the parse levels below, in order of precedence
   * @return {Node} node
   * @private
   */
  function parseStart(expression, extraNodes) {
    const state = initialState();
    (0, _extends2.default)(state, {
      expression,
      extraNodes
    });
    getToken(state);
    const node = parseBlock(state);

    // check for garbage at the end of the expression
    // an expression ends with a empty character '' and tokenType DELIMITER
    if (state.token !== '') {
      if (state.tokenType === TOKENTYPE.DELIMITER) {
        // user entered a not existing operator like "//"

        // TODO: give hints for aliases, for example with "<>" give as hint " did you mean !== ?"
        throw createError(state, 'Unexpected operator ' + state.token);
      } else {
        throw createSyntaxError(state, 'Unexpected part "' + state.token + '"');
      }
    }
    return node;
  }

  /**
   * Parse a block with expressions. Expressions can be separated by a newline
   * character '\n', or by a semicolon ';'. In case of a semicolon, no output
   * of the preceding line is returned.
   * @return {Node} node
   * @private
   */
  function parseBlock(state) {
    let node;
    const blocks = [];
    let visible;
    if (state.token !== '' && state.token !== '\n' && state.token !== ';') {
      node = parseAssignment(state);
      if (state.comment) {
        node.comment = state.comment;
      }
    }

    // TODO: simplify this loop
    while (state.token === '\n' || state.token === ';') {
      // eslint-disable-line no-unmodified-loop-condition
      if (blocks.length === 0 && node) {
        visible = state.token !== ';';
        blocks.push({
          node,
          visible
        });
      }
      getToken(state);
      if (state.token !== '\n' && state.token !== ';' && state.token !== '') {
        node = parseAssignment(state);
        if (state.comment) {
          node.comment = state.comment;
        }
        visible = state.token !== ';';
        blocks.push({
          node,
          visible
        });
      }
    }
    if (blocks.length > 0) {
      return new BlockNode(blocks);
    } else {
      if (!node) {
        node = new ConstantNode(undefined);
        if (state.comment) {
          node.comment = state.comment;
        }
      }
      return node;
    }
  }

  /**
   * Assignment of a function or variable,
   * - can be a variable like 'a=2.3'
   * - or a updating an existing variable like 'matrix(2,3:5)=[6,7,8]'
   * - defining a function like 'f(x) = x^2'
   * @return {Node} node
   * @private
   */
  function parseAssignment(state) {
    let name, args, value, valid;
    const node = parseConditional(state);
    if (state.token === '=') {
      if ((0, _is.isSymbolNode)(node)) {
        // parse a variable assignment like 'a = 2/3'
        name = node.name;
        getTokenSkipNewline(state);
        value = parseAssignment(state);
        return new AssignmentNode(new SymbolNode(name), value);
      } else if ((0, _is.isAccessorNode)(node)) {
        // parse a matrix subset assignment like 'A[1,2] = 4'
        getTokenSkipNewline(state);
        value = parseAssignment(state);
        return new AssignmentNode(node.object, node.index, value);
      } else if ((0, _is.isFunctionNode)(node) && (0, _is.isSymbolNode)(node.fn)) {
        // parse function assignment like 'f(x) = x^2'
        valid = true;
        args = [];
        name = node.name;
        node.args.forEach(function (arg, index) {
          if ((0, _is.isSymbolNode)(arg)) {
            args[index] = arg.name;
          } else {
            valid = false;
          }
        });
        if (valid) {
          getTokenSkipNewline(state);
          value = parseAssignment(state);
          return new FunctionAssignmentNode(name, args, value);
        }
      }
      throw createSyntaxError(state, 'Invalid left hand side of assignment operator =');
    }
    return node;
  }

  /**
   * conditional operation
   *
   *     condition ? truePart : falsePart
   *
   * Note: conditional operator is right-associative
   *
   * @return {Node} node
   * @private
   */
  function parseConditional(state) {
    let node = parseLogicalOr(state);
    while (state.token === '?') {
      // eslint-disable-line no-unmodified-loop-condition
      // set a conditional level, the range operator will be ignored as long
      // as conditionalLevel === state.nestingLevel.
      const prev = state.conditionalLevel;
      state.conditionalLevel = state.nestingLevel;
      getTokenSkipNewline(state);
      const condition = node;
      const trueExpr = parseAssignment(state);
      if (state.token !== ':') throw createSyntaxError(state, 'False part of conditional expression expected');
      state.conditionalLevel = null;
      getTokenSkipNewline(state);
      const falseExpr = parseAssignment(state); // Note: check for conditional operator again, right associativity

      node = new ConditionalNode(condition, trueExpr, falseExpr);

      // restore the previous conditional level
      state.conditionalLevel = prev;
    }
    return node;
  }

  /**
   * logical or, 'x or y'
   * @return {Node} node
   * @private
   */
  function parseLogicalOr(state) {
    let node = parseLogicalXor(state);
    while (state.token === 'or') {
      // eslint-disable-line no-unmodified-loop-condition
      getTokenSkipNewline(state);
      node = new OperatorNode('or', 'or', [node, parseLogicalXor(state)]);
    }
    return node;
  }

  /**
   * logical exclusive or, 'x xor y'
   * @return {Node} node
   * @private
   */
  function parseLogicalXor(state) {
    let node = parseLogicalAnd(state);
    while (state.token === 'xor') {
      // eslint-disable-line no-unmodified-loop-condition
      getTokenSkipNewline(state);
      node = new OperatorNode('xor', 'xor', [node, parseLogicalAnd(state)]);
    }
    return node;
  }

  /**
   * logical and, 'x and y'
   * @return {Node} node
   * @private
   */
  function parseLogicalAnd(state) {
    let node = parseBitwiseOr(state);
    while (state.token === 'and') {
      // eslint-disable-line no-unmodified-loop-condition
      getTokenSkipNewline(state);
      node = new OperatorNode('and', 'and', [node, parseBitwiseOr(state)]);
    }
    return node;
  }

  /**
   * bitwise or, 'x | y'
   * @return {Node} node
   * @private
   */
  function parseBitwiseOr(state) {
    let node = parseBitwiseXor(state);
    while (state.token === '|') {
      // eslint-disable-line no-unmodified-loop-condition
      getTokenSkipNewline(state);
      node = new OperatorNode('|', 'bitOr', [node, parseBitwiseXor(state)]);
    }
    return node;
  }

  /**
   * bitwise exclusive or (xor), 'x ^| y'
   * @return {Node} node
   * @private
   */
  function parseBitwiseXor(state) {
    let node = parseBitwiseAnd(state);
    while (state.token === '^|') {
      // eslint-disable-line no-unmodified-loop-condition
      getTokenSkipNewline(state);
      node = new OperatorNode('^|', 'bitXor', [node, parseBitwiseAnd(state)]);
    }
    return node;
  }

  /**
   * bitwise and, 'x & y'
   * @return {Node} node
   * @private
   */
  function parseBitwiseAnd(state) {
    let node = parseRelational(state);
    while (state.token === '&') {
      // eslint-disable-line no-unmodified-loop-condition
      getTokenSkipNewline(state);
      node = new OperatorNode('&', 'bitAnd', [node, parseRelational(state)]);
    }
    return node;
  }

  /**
   * Parse a chained conditional, like 'a > b >= c'
   * @return {Node} node
   */
  function parseRelational(state) {
    const params = [parseShift(state)];
    const conditionals = [];
    const operators = {
      '==': 'equal',
      '!=': 'unequal',
      '<': 'smaller',
      '>': 'larger',
      '<=': 'smallerEq',
      '>=': 'largerEq'
    };
    while ((0, _object.hasOwnProperty)(operators, state.token)) {
      // eslint-disable-line no-unmodified-loop-condition
      const cond = {
        name: state.token,
        fn: operators[state.token]
      };
      conditionals.push(cond);
      getTokenSkipNewline(state);
      params.push(parseShift(state));
    }
    if (params.length === 1) {
      return params[0];
    } else if (params.length === 2) {
      return new OperatorNode(conditionals[0].name, conditionals[0].fn, params);
    } else {
      return new RelationalNode(conditionals.map(c => c.fn), params);
    }
  }

  /**
   * Bitwise left shift, bitwise right arithmetic shift, bitwise right logical shift
   * @return {Node} node
   * @private
   */
  function parseShift(state) {
    let node, name, fn, params;
    node = parseConversion(state);
    const operators = {
      '<<': 'leftShift',
      '>>': 'rightArithShift',
      '>>>': 'rightLogShift'
    };
    while ((0, _object.hasOwnProperty)(operators, state.token)) {
      name = state.token;
      fn = operators[name];
      getTokenSkipNewline(state);
      params = [node, parseConversion(state)];
      node = new OperatorNode(name, fn, params);
    }
    return node;
  }

  /**
   * conversion operators 'to' and 'in'
   * @return {Node} node
   * @private
   */
  function parseConversion(state) {
    let node, name, fn, params;
    node = parseRange(state);
    const operators = {
      to: 'to',
      in: 'to' // alias of 'to'
    };
    while ((0, _object.hasOwnProperty)(operators, state.token)) {
      name = state.token;
      fn = operators[name];
      getTokenSkipNewline(state);
      if (name === 'in' && state.token === '') {
        // end of expression -> this is the unit 'in' ('inch')
        node = new OperatorNode('*', 'multiply', [node, new SymbolNode('in')], true);
      } else {
        // operator 'a to b' or 'a in b'
        params = [node, parseRange(state)];
        node = new OperatorNode(name, fn, params);
      }
    }
    return node;
  }

  /**
   * parse range, "start:end", "start:step:end", ":", "start:", ":end", etc
   * @return {Node} node
   * @private
   */
  function parseRange(state) {
    let node;
    const params = [];
    if (state.token === ':') {
      // implicit start=1 (one-based)
      node = new ConstantNode(1);
    } else {
      // explicit start
      node = parseAddSubtract(state);
    }
    if (state.token === ':' && state.conditionalLevel !== state.nestingLevel) {
      // we ignore the range operator when a conditional operator is being processed on the same level
      params.push(node);

      // parse step and end
      while (state.token === ':' && params.length < 3) {
        // eslint-disable-line no-unmodified-loop-condition
        getTokenSkipNewline(state);
        if (state.token === ')' || state.token === ']' || state.token === ',' || state.token === '') {
          // implicit end
          params.push(new SymbolNode('end'));
        } else {
          // explicit end
          params.push(parseAddSubtract(state));
        }
      }
      if (params.length === 3) {
        // params = [start, step, end]
        node = new RangeNode(params[0], params[2], params[1]); // start, end, step
      } else {
        // length === 2
        // params = [start, end]
        node = new RangeNode(params[0], params[1]); // start, end
      }
    }
    return node;
  }

  /**
   * add or subtract
   * @return {Node} node
   * @private
   */
  function parseAddSubtract(state) {
    let node, name, fn, params;
    node = parseMultiplyDivideModulusPercentage(state);
    const operators = {
      '+': 'add',
      '-': 'subtract'
    };
    while ((0, _object.hasOwnProperty)(operators, state.token)) {
      name = state.token;
      fn = operators[name];
      getTokenSkipNewline(state);
      const rightNode = parseMultiplyDivideModulusPercentage(state);
      if (rightNode.isPercentage) {
        params = [node, new OperatorNode('*', 'multiply', [node, rightNode])];
      } else {
        params = [node, rightNode];
      }
      node = new OperatorNode(name, fn, params);
    }
    return node;
  }

  /**
   * multiply, divide, modulus, percentage
   * @return {Node} node
   * @private
   */
  function parseMultiplyDivideModulusPercentage(state) {
    let node, last, name, fn;
    node = parseImplicitMultiplication(state);
    last = node;
    const operators = {
      '*': 'multiply',
      '.*': 'dotMultiply',
      '/': 'divide',
      './': 'dotDivide',
      '%': 'mod',
      mod: 'mod'
    };
    while (true) {
      if ((0, _object.hasOwnProperty)(operators, state.token)) {
        // explicit operators
        name = state.token;
        fn = operators[name];
        getTokenSkipNewline(state);
        if (name === '%' && state.tokenType === TOKENTYPE.DELIMITER && state.token !== '(') {
          // If the expression contains only %, then treat that as /100
          if (state.token !== '' && operators[state.token]) {
            const left = new OperatorNode('/', 'divide', [node, new ConstantNode(100)], false, true);
            name = state.token;
            fn = operators[name];
            getTokenSkipNewline(state);
            last = parseImplicitMultiplication(state);
            node = new OperatorNode(name, fn, [left, last]);
          } else {
            node = new OperatorNode('/', 'divide', [node, new ConstantNode(100)], false, true);
          }
          // return node
        } else {
          last = parseImplicitMultiplication(state);
          node = new OperatorNode(name, fn, [node, last]);
        }
      } else {
        break;
      }
    }
    return node;
  }

  /**
   * implicit multiplication
   * @return {Node} node
   * @private
   */
  function parseImplicitMultiplication(state) {
    let node, last;
    node = parseRule2(state);
    last = node;
    while (true) {
      if (state.tokenType === TOKENTYPE.SYMBOL || state.token === 'in' && (0, _is.isConstantNode)(node) || state.token === 'in' && (0, _is.isOperatorNode)(node) && node.fn === 'unaryMinus' && (0, _is.isConstantNode)(node.args[0]) || state.tokenType === TOKENTYPE.NUMBER && !(0, _is.isConstantNode)(last) && (!(0, _is.isOperatorNode)(last) || last.op === '!') || state.token === '(') {
        // parse implicit multiplication
        //
        // symbol:      implicit multiplication like '2a', '(2+3)a', 'a b'
        // number:      implicit multiplication like '(2+3)2'
        // parenthesis: implicit multiplication like '2(3+4)', '(3+4)(1+2)'
        last = parseRule2(state);
        node = new OperatorNode('*', 'multiply', [node, last], true /* implicit */);
      } else {
        break;
      }
    }
    return node;
  }

  /**
   * Infamous "rule 2" as described in https://github.com/josdejong/mathjs/issues/792#issuecomment-361065370
   * And as amended in https://github.com/josdejong/mathjs/issues/2370#issuecomment-1054052164
   * Explicit division gets higher precedence than implicit multiplication
   * when the division matches this pattern:
   *   [unaryPrefixOp]?[number] / [number] [symbol]
   * @return {Node} node
   * @private
   */
  function parseRule2(state) {
    let node = parseUnary(state);
    let last = node;
    const tokenStates = [];
    while (true) {
      // Match the "number /" part of the pattern "number / number symbol"
      if (state.token === '/' && (0, _is.rule2Node)(last)) {
        // Look ahead to see if the next token is a number
        tokenStates.push((0, _extends2.default)({}, state));
        getTokenSkipNewline(state);

        // Match the "number / number" part of the pattern
        if (state.tokenType === TOKENTYPE.NUMBER) {
          // Look ahead again
          tokenStates.push((0, _extends2.default)({}, state));
          getTokenSkipNewline(state);

          // Match the "symbol" part of the pattern, or a left parenthesis
          if (state.tokenType === TOKENTYPE.SYMBOL || state.token === '(' || state.token === 'in') {
            // We've matched the pattern "number / number symbol".
            // Rewind once and build the "number / number" node; the symbol will be consumed later
            (0, _extends2.default)(state, tokenStates.pop());
            tokenStates.pop();
            last = parseUnary(state);
            node = new OperatorNode('/', 'divide', [node, last]);
          } else {
            // Not a match, so rewind
            tokenStates.pop();
            (0, _extends2.default)(state, tokenStates.pop());
            break;
          }
        } else {
          // Not a match, so rewind
          (0, _extends2.default)(state, tokenStates.pop());
          break;
        }
      } else {
        break;
      }
    }
    return node;
  }

  /**
   * Unary plus and minus, and logical and bitwise not
   * @return {Node} node
   * @private
   */
  function parseUnary(state) {
    let name, params, fn;
    const operators = {
      '-': 'unaryMinus',
      '+': 'unaryPlus',
      '~': 'bitNot',
      not: 'not'
    };
    if ((0, _object.hasOwnProperty)(operators, state.token)) {
      fn = operators[state.token];
      name = state.token;
      getTokenSkipNewline(state);
      params = [parseUnary(state)];
      return new OperatorNode(name, fn, params);
    }
    return parsePow(state);
  }

  /**
   * power
   * Note: power operator is right associative
   * @return {Node} node
   * @private
   */
  function parsePow(state) {
    let node, name, fn, params;
    node = parseLeftHandOperators(state);
    if (state.token === '^' || state.token === '.^') {
      name = state.token;
      fn = name === '^' ? 'pow' : 'dotPow';
      getTokenSkipNewline(state);
      params = [node, parseUnary(state)]; // Go back to unary, we can have '2^-3'
      node = new OperatorNode(name, fn, params);
    }
    return node;
  }

  /**
   * Left hand operators: factorial x!, ctranspose x'
   * @return {Node} node
   * @private
   */
  function parseLeftHandOperators(state) {
    let node, name, fn, params;
    node = parseCustomNodes(state);
    const operators = {
      '!': 'factorial',
      '\'': 'ctranspose'
    };
    while ((0, _object.hasOwnProperty)(operators, state.token)) {
      name = state.token;
      fn = operators[name];
      getToken(state);
      params = [node];
      node = new OperatorNode(name, fn, params);
      node = parseAccessors(state, node);
    }
    return node;
  }

  /**
   * Parse a custom node handler. A node handler can be used to process
   * nodes in a custom way, for example for handling a plot.
   *
   * A handler must be passed as second argument of the parse function.
   * - must extend math.Node
   * - must contain a function _compile(defs: Object) : string
   * - must contain a function find(filter: Object) : Node[]
   * - must contain a function toString() : string
   * - the constructor is called with a single argument containing all parameters
   *
   * For example:
   *
   *     nodes = {
   *       'plot': PlotHandler
   *     }
   *
   * The constructor of the handler is called as:
   *
   *     node = new PlotHandler(params)
   *
   * The handler will be invoked when evaluating an expression like:
   *
   *     node = math.parse('plot(sin(x), x)', nodes)
   *
   * @return {Node} node
   * @private
   */
  function parseCustomNodes(state) {
    let params = [];
    if (state.tokenType === TOKENTYPE.SYMBOL && (0, _object.hasOwnProperty)(state.extraNodes, state.token)) {
      const CustomNode = state.extraNodes[state.token];
      getToken(state);

      // parse parameters
      if (state.token === '(') {
        params = [];
        openParams(state);
        getToken(state);
        if (state.token !== ')') {
          params.push(parseAssignment(state));

          // parse a list with parameters
          while (state.token === ',') {
            // eslint-disable-line no-unmodified-loop-condition
            getToken(state);
            params.push(parseAssignment(state));
          }
        }
        if (state.token !== ')') {
          throw createSyntaxError(state, 'Parenthesis ) expected');
        }
        closeParams(state);
        getToken(state);
      }

      // create a new custom node
      // noinspection JSValidateTypes
      return new CustomNode(params);
    }
    return parseSymbol(state);
  }

  /**
   * parse symbols: functions, variables, constants, units
   * @return {Node} node
   * @private
   */
  function parseSymbol(state) {
    let node, name;
    if (state.tokenType === TOKENTYPE.SYMBOL || state.tokenType === TOKENTYPE.DELIMITER && state.token in NAMED_DELIMITERS) {
      name = state.token;
      getToken(state);
      if ((0, _object.hasOwnProperty)(CONSTANTS, name)) {
        // true, false, null, ...
        node = new ConstantNode(CONSTANTS[name]);
      } else if (NUMERIC_CONSTANTS.includes(name)) {
        // NaN, Infinity
        node = new ConstantNode(numeric(name, 'number'));
      } else {
        node = new SymbolNode(name);
      }

      // parse function parameters and matrix index
      node = parseAccessors(state, node);
      return node;
    }
    return parseString(state);
  }

  /**
   * parse accessors:
   * - function invocation in round brackets (...), for example sqrt(2)
   * - index enclosed in square brackets [...], for example A[2,3]
   * - dot notation for properties, like foo.bar
   * @param {Object} state
   * @param {Node} node    Node on which to apply the parameters. If there
   *                       are no parameters in the expression, the node
   *                       itself is returned
   * @param {string[]} [types]  Filter the types of notations
   *                            can be ['(', '[', '.']
   * @return {Node} node
   * @private
   */
  function parseAccessors(state, node, types) {
    let params;
    while ((state.token === '(' || state.token === '[' || state.token === '.') && (!types || types.includes(state.token))) {
      // eslint-disable-line no-unmodified-loop-condition
      params = [];
      if (state.token === '(') {
        if ((0, _is.isSymbolNode)(node) || (0, _is.isAccessorNode)(node)) {
          // function invocation like fn(2, 3) or obj.fn(2, 3)
          openParams(state);
          getToken(state);
          if (state.token !== ')') {
            params.push(parseAssignment(state));

            // parse a list with parameters
            while (state.token === ',') {
              // eslint-disable-line no-unmodified-loop-condition
              getToken(state);
              params.push(parseAssignment(state));
            }
          }
          if (state.token !== ')') {
            throw createSyntaxError(state, 'Parenthesis ) expected');
          }
          closeParams(state);
          getToken(state);
          node = new FunctionNode(node, params);
        } else {
          // implicit multiplication like (2+3)(4+5) or sqrt(2)(1+2)
          // don't parse it here but let it be handled by parseImplicitMultiplication
          // with correct precedence
          return node;
        }
      } else if (state.token === '[') {
        // index notation like variable[2, 3]
        openParams(state);
        getToken(state);
        if (state.token !== ']') {
          params.push(parseAssignment(state));

          // parse a list with parameters
          while (state.token === ',') {
            // eslint-disable-line no-unmodified-loop-condition
            getToken(state);
            params.push(parseAssignment(state));
          }
        }
        if (state.token !== ']') {
          throw createSyntaxError(state, 'Parenthesis ] expected');
        }
        closeParams(state);
        getToken(state);
        node = new AccessorNode(node, new IndexNode(params));
      } else {
        // dot notation like variable.prop
        getToken(state);
        const isPropertyName = state.tokenType === TOKENTYPE.SYMBOL || state.tokenType === TOKENTYPE.DELIMITER && state.token in NAMED_DELIMITERS;
        if (!isPropertyName) {
          throw createSyntaxError(state, 'Property name expected after dot');
        }
        params.push(new ConstantNode(state.token));
        getToken(state);
        const dotNotation = true;
        node = new AccessorNode(node, new IndexNode(params, dotNotation));
      }
    }
    return node;
  }

  /**
   * Parse a single or double quoted string.
   * @return {Node} node
   * @private
   */
  function parseString(state) {
    let node, str;
    if (state.token === '"' || state.token === "'") {
      str = parseStringToken(state, state.token);

      // create constant
      node = new ConstantNode(str);

      // parse index parameters
      node = parseAccessors(state, node);
      return node;
    }
    return parseMatrix(state);
  }

  /**
   * Parse a string surrounded by single or double quotes
   * @param {Object} state
   * @param {"'" | "\""} quote
   * @return {string}
   */
  function parseStringToken(state, quote) {
    let str = '';
    while (currentCharacter(state) !== '' && currentCharacter(state) !== quote) {
      if (currentCharacter(state) === '\\') {
        next(state);
        const char = currentCharacter(state);
        const escapeChar = ESCAPE_CHARACTERS[char];
        if (escapeChar !== undefined) {
          // an escaped control character like \" or \n
          str += escapeChar;
          state.index += 1;
        } else if (char === 'u') {
          // escaped unicode character
          const unicode = state.expression.slice(state.index + 1, state.index + 5);
          if (/^[0-9A-Fa-f]{4}$/.test(unicode)) {
            // test whether the string holds four hexadecimal values
            str += String.fromCharCode(parseInt(unicode, 16));
            state.index += 5;
          } else {
            throw createSyntaxError(state, `Invalid unicode character \\u${unicode}`);
          }
        } else {
          throw createSyntaxError(state, `Bad escape character \\${char}`);
        }
      } else {
        // any regular character
        str += currentCharacter(state);
        next(state);
      }
    }
    getToken(state);
    if (state.token !== quote) {
      throw createSyntaxError(state, `End of string ${quote} expected`);
    }
    getToken(state);
    return str;
  }

  /**
   * parse the matrix
   * @return {Node} node
   * @private
   */
  function parseMatrix(state) {
    let array, params, rows, cols;
    if (state.token === '[') {
      // matrix [...]
      openParams(state);
      getToken(state);
      if (state.token !== ']') {
        // this is a non-empty matrix
        const row = parseRow(state);
        if (state.token === ';') {
          // 2 dimensional array
          rows = 1;
          params = [row];

          // the rows of the matrix are separated by dot-comma's
          while (state.token === ';') {
            // eslint-disable-line no-unmodified-loop-condition
            getToken(state);
            if (state.token !== ']') {
              params[rows] = parseRow(state);
              rows++;
            }
          }
          if (state.token !== ']') {
            throw createSyntaxError(state, 'End of matrix ] expected');
          }
          closeParams(state);
          getToken(state);

          // check if the number of columns matches in all rows
          cols = params[0].items.length;
          for (let r = 1; r < rows; r++) {
            if (params[r].items.length !== cols) {
              throw createError(state, 'Column dimensions mismatch ' + '(' + params[r].items.length + ' !== ' + cols + ')');
            }
          }
          array = new ArrayNode(params);
        } else {
          // 1 dimensional vector
          if (state.token !== ']') {
            throw createSyntaxError(state, 'End of matrix ] expected');
          }
          closeParams(state);
          getToken(state);
          array = row;
        }
      } else {
        // this is an empty matrix "[ ]"
        closeParams(state);
        getToken(state);
        array = new ArrayNode([]);
      }
      return parseAccessors(state, array);
    }
    return parseObject(state);
  }

  /**
   * Parse a single comma-separated row from a matrix, like 'a, b, c'
   * @return {ArrayNode} node
   */
  function parseRow(state) {
    const params = [parseAssignment(state)];
    let len = 1;
    while (state.token === ',') {
      // eslint-disable-line no-unmodified-loop-condition
      getToken(state);

      // parse expression
      if (state.token !== ']' && state.token !== ';') {
        params[len] = parseAssignment(state);
        len++;
      }
    }
    return new ArrayNode(params);
  }

  /**
   * parse an object, enclosed in angle brackets{...}, for example {value: 2}
   * @return {Node} node
   * @private
   */
  function parseObject(state) {
    if (state.token === '{') {
      openParams(state);
      let key;
      const properties = {};
      do {
        getToken(state);
        if (state.token !== '}') {
          // parse key
          if (state.token === '"' || state.token === "'") {
            key = parseStringToken(state, state.token);
          } else if (state.tokenType === TOKENTYPE.SYMBOL || state.tokenType === TOKENTYPE.DELIMITER && state.token in NAMED_DELIMITERS) {
            key = state.token;
            getToken(state);
          } else {
            throw createSyntaxError(state, 'Symbol or string expected as object key');
          }

          // parse key/value separator
          if (state.token !== ':') {
            throw createSyntaxError(state, 'Colon : expected after object key');
          }
          getToken(state);

          // parse key
          properties[key] = parseAssignment(state);
        }
      } while (state.token === ','); // eslint-disable-line no-unmodified-loop-condition

      if (state.token !== '}') {
        throw createSyntaxError(state, 'Comma , or bracket } expected after object value');
      }
      closeParams(state);
      getToken(state);
      let node = new ObjectNode(properties);

      // parse index parameters
      node = parseAccessors(state, node);
      return node;
    }
    return parseNumber(state);
  }

  /**
   * parse a number
   * @return {Node} node
   * @private
   */
  function parseNumber(state) {
    let numberStr;
    if (state.tokenType === TOKENTYPE.NUMBER) {
      // this is a number
      numberStr = state.token;
      getToken(state);
      const numericType = (0, _number.safeNumberType)(numberStr, config);
      const value = numeric(numberStr, numericType);
      return new ConstantNode(value);
    }
    return parseParentheses(state);
  }

  /**
   * parentheses
   * @return {Node} node
   * @private
   */
  function parseParentheses(state) {
    let node;

    // check if it is a parenthesized expression
    if (state.token === '(') {
      // parentheses (...)
      openParams(state);
      getToken(state);
      node = parseAssignment(state); // start again

      if (state.token !== ')') {
        throw createSyntaxError(state, 'Parenthesis ) expected');
      }
      closeParams(state);
      getToken(state);
      node = new ParenthesisNode(node);
      node = parseAccessors(state, node);
      return node;
    }
    return parseEnd(state);
  }

  /**
   * Evaluated when the expression is not yet ended but expected to end
   * @return {Node} res
   * @private
   */
  function parseEnd(state) {
    if (state.token === '') {
      // syntax error or unexpected end of expression
      throw createSyntaxError(state, 'Unexpected end of expression');
    } else {
      throw createSyntaxError(state, 'Value expected');
    }
  }

  /**
   * Shortcut for getting the current row value (one based)
   * Returns the line of the currently handled expression
   * @private
   */
  /* TODO: implement keeping track on the row number
  function row () {
    return null
  }
  */

  /**
   * Shortcut for getting the current col value (one based)
   * Returns the column (position) where the last state.token starts
   * @private
   */
  function col(state) {
    return state.index - state.token.length + 1;
  }

  /**
   * Create an error
   * @param {Object} state
   * @param {string} message
   * @return {SyntaxError} instantiated error
   * @private
   */
  function createSyntaxError(state, message) {
    const c = col(state);
    const error = new SyntaxError(message + ' (char ' + c + ')');
    error.char = c;
    return error;
  }

  /**
   * Create an error
   * @param {Object} state
   * @param {string} message
   * @return {Error} instantiated error
   * @private
   */
  function createError(state, message) {
    const c = col(state);
    const error = new SyntaxError(message + ' (char ' + c + ')');
    error.char = c;
    return error;
  }

  // Now that we can parse, automatically convert strings to Nodes by parsing
  typed.addConversion({
    from: 'string',
    to: 'Node',
    convert: parse
  });
  return parse;
});